JP6627178B2 - Bridge girder support structure - Google Patents

Description

  The present invention relates to a bridge girder support structure applied to bridges such as railway bridges and road bridges.

In a conventional general bridge, a bridge girder support structure for supporting a support for supporting a bridge girder on a pier serving as a pedestal by an anchor bolt is incorporated.
The bridge girder support structure 1 shown in FIG. 4 has an anchor bolt 3 having a base end 3A embedded in a pier 2 and an upper end 3B provided so as to protrude from the pier 2.
The anchor bolt 3 is disposed so as to be perpendicular to the pier 2 and is installed so as to vertically pass through a through hole 5 of a support body 4 installed on the pier 2.

The support body 4 includes a base plate 6 located at a lower portion, a support rubber main body 7 installed on the base plate 6, and an upper plate 8 laminated on the support rubber main body 7. A bridge girder 10 is fixed on the plate 8.
The bridge girder 10 has an upper flange 11 located at an upper part, a lower flange 12 located at a lower part, and a girder main body 13 connecting these two flanges 11, 12. Are connected and fixed to the upper plate 8 of the support 4 via set bolts 14.
It should be noted that, besides the form of the above-mentioned support body, the structure of the base plate and the anchor bolt is the same in steel supports such as a pin support, a pivot support, and a support plate support, and is an object of the present invention.

On the other hand, the through hole 5 through which the upper end 3B of the anchor bolt 3 is inserted is formed so as to vertically pass through the base plate 6 of the support body 4.
A nut 16 is screwed into the upper end portion 3B of the anchor bolt 3 penetrating the base plate 6 of the support body 4 through a washer 15. The support body 4 is mounted on the pier 2 by fastening the nut 16. It is fixed.

As a technique related to the bridge girder support structure, for example, a bearing device disclosed in Patent Document 1 is known.
The bearing device described in Patent Document 1 has a cylindrical coupler body having an outer diameter substantially the same as the inner diameter of a mounting hole formed in a bearing device mounting plate. An anchor bolt fixed to the lower structure of such a structure is screwed.

JP 2010-216086 A

In the structure shown in Patent Literature 1 and FIG. 4 described above, the anchor bolt 3 is embedded in the pier 2 and the upper end of the anchor bolt 3 protruding from the pier 2 is screwed by the nut 16 (Patent Literature). In No. 1, the anchor bolt is screwed to the coupler body.
For this reason, when the bearing 4 integrated with the bridge girder 10 is lifted by the upward lift during an earthquake, the upward lift of the support 4 also acts on the anchor bolt 3, whereby the anchor bolt 3 In some cases, the concrete pier 2 in which the concrete 3 is embedded is destroyed.
When such concrete damage occurs, there is a problem that it is difficult to recover the pier 2 after the earthquake. A similar problem also occurs when ribs and studs are provided on the pier 2 to generate a horizontal resistance.

  The present invention has been made in view of the above-described circumstances, and even when a strong lifting force is generated on a support body integrated with a bridge girder at the time of an earthquake, the lifting force is increased by an anchor bolt. And a bridge girder supporting structure capable of preventing the bridge pier from being broken by preventing the bridge pier from being transmitted to the pier via the bridge pier.

In order to solve the above problems, the present invention proposes the following means.
That is, according to the present invention, in a bridge in which a bridge girder is supported on a pier via a bearing, an anchor bolt having a base end embedded in the pier and having an upper end provided so as to protrude upward from the pier. A hole provided in the support body installed on the pier and through which an upper end of the anchor bolt is inserted; and a nut screwed to the upper end of the anchor bolt passing through the hole of the support body. A resistance member disposed between the opening edge of the hole of the support body and the nut and transmitting a fastening force of the nut to the support body, wherein the resistance member vertically displaces the support body. Accordingly, the anchor bolt is deformed more than the anchor bolt. For example, the resistance member 30 is formed in a shape larger than the through hole 25 of the support 22, and the nut 31 is formed smaller in diameter than the through hole 25 of the support 22.

According to the present invention, the upper end of the anchor bolt protruding upward from the bridge pier passes through the hole of the support body supporting the bridge girder, and is then screwed to the nut via the resistance member. Then, by the fastening of the nut via such a resistance member, the support body supporting the bridge girder is fixed on the anchor bolt of the pier.
At this time, the resistance member located on the hole of the support body is elastically deformed more easily than the anchor bolt. In addition, the nut which is formed in a shape larger than the hole of the support body and which holds the resistance member is formed to have a smaller diameter than the hole of the support body, whereby the resistance member in contact with the opening edge of the hole of the support body is formed. The peripheral portion does not overlap the nut in the horizontal direction, and can be easily deformed when pressed at the opening edge of the hole of the support.
Accordingly, in the present invention, when a strong lifting force is generated in the support body integrated with the bridge girder at the time of an earthquake, the peripheral edge of the resistance member in contact with the opening edge of the hole of the support body is deformed. be able to. At this time, when the lifting force of the support body is a large value exceeding the elastic limit point of the resistance member (for example, when a large earthquake occurs), the resistance member undergoes plastic deformation, and as a result, The lifting force of the support body can be prevented from being transmitted to the pier via the anchor bolt, and the pier can be prevented from being broken.
That is, according to the present invention, among the forces acting on the anchor bolts from the bearing body during an earthquake, the forces along the axial direction of the anchor bolts are released by deformation of the resistance member, thereby causing a large damage to the pier through the anchor bolts. Can be prevented from occurring.

  In the present invention, the resistance member is formed in a ring shape so as to surround the anchor bolt from the periphery.

  Further, according to the present invention, since the resistance member disposed between the opening edge of the hole of the support and the nut is formed in a ring shape so as to surround the anchor bolt from the periphery, the fastening force of the nut is reduced. It can be evenly transmitted to the support.

  Further, in the present invention, the resistance member is constituted by a washer.

  According to the present invention, a bridge girder support structure can be constructed at low cost by using a general-purpose washer as a resistance member.

  Further, in the present invention, an upper end portion of the anchor bolt protruding from the pier is set to a size such that the bearing body does not come out upward when an earthquake occurs.

  According to the present invention, since the upper end portion of the anchor bolt projecting from the pier is set to a size such that the bearing body does not come out upward in the event of an earthquake, the resistance member in the hole of the bearing body has an anchor. Even if the bolts move relative to each other along the axial direction, the bearing does not fall off the pier, and in this regard, damage from the earthquake can be minimized.

According to the present invention, when a strong lifting force is generated in the support body integrated with the bridge girder during the occurrence of an earthquake, the peripheral edge of the resistance member in contact with the opening edge of the hole of the support can be deformed. . At this time, when the lifting force of the support body is a large value exceeding the elastic limit point of the resistance member (for example, when a large earthquake occurs), the resistance member undergoes plastic deformation, and as a result, The lifting force of the support body can be prevented from being transmitted to the pier via the anchor bolt, and the pier can be prevented from being broken.
That is, according to the present invention, among the forces acting on the anchor bolts from the bearing body during an earthquake, the forces along the axial direction of the anchor bolts are released by deformation of the resistance member, thereby causing a large damage to the pier through the anchor bolts. Can be prevented from occurring.

1 is a front sectional view of a bridge girder support structure according to an embodiment of the present invention. 2A is a front cross-sectional view showing a main part of the bridge girder support structure of FIG. 1, and FIG. 2B is a diagram when a large external force is applied to a support of the bridge girder support structure of FIG. It is a graph which shows the amount of displacement (x-axis) at the time of applying an upward lift to a support body, and the load (y-axis) applied to an anchor bolt. It is a front sectional view showing the conventional bridge girder support structure.

An embodiment of a bridge girder support structure 100 according to the present invention will be described with reference to FIGS.
In FIGS. 1 and 2, a bridge denoted by reference numeral 20 is a bridge having a structure in which a bridge girder (not shown) is supported on a pier 21 via a support 22.
An anchor bolt 24 is arranged on the pier 21 so that the base end portion 24A is embedded therein. The anchor bolt 24 is disposed so as to be perpendicular to the pier 21 (in the direction of the arrow (a)), and is provided with an upper end 24B so as to protrude from the pier 21. Are installed so as to vertically penetrate through holes 25 of the support body 22 installed on the pier 21.

The support body 22 includes a base plate 26 located at a lower part, a support rubber main body 27 installed on the base plate 26, and an upper plate (not shown) laminated on the support rubber main body 27. A bridge girder (not shown) is fixed on the upper plate via set bolts.
The through hole 25 into which the upper end 24B of the anchor bolt 24 is inserted is formed so as to vertically pass through the base plate 26 of the support body 22.
The configurations of the bridge girder and the set bolt are the same as those in FIG.

  As shown in FIG. 1, a nut 31 is screwed to an upper end portion 24 </ b> B of the anchor bolt 24 penetrating the base plate 26 of the support body 22 via a ring-shaped resistance member 30. Thereby, the base plate 26 of the support body 22 is fixed on the pier 21.

As shown in FIG. 2, the resistance member 30 is made of a washer having a diameter (indicated by reference numeral 30 a) larger than the diameter (indicated by reference numeral 25 a) of the through hole 25. It is located between the opening edge 25A formed at the inlet and the lower surface of the nut 31, and transmits the fastening force of the nut 31 to the support 22.
The nut 31 is formed to have a smaller diameter (indicated by reference numeral 31a) than the diameter 25a of the through hole 25 of the support body 22.

As shown in FIG. 2A, the opening edge of the support 22 is determined by the dimensional relationship between the diameter 25a of the through hole 25 of the support 22, the diameter 30a of the resistance member 30, and the diameter 31a of the nut 31. The peripheral edge 30A of the resistance member 30 in contact with the portion 25A does not overlap with the nut 31 in the horizontal direction (arrow (b) direction), and can be easily deformed when pressed by the opening edge 25A of the support body 22. Become.
Accordingly, in the present embodiment, as shown in FIG. 2B, when an earthquake occurs, the strong lifting force (in the direction of the arrow (a)) of the support 22 integrated with the bridge girder along the axial direction (arrow (a) direction). (Indicated by reference numeral F), the peripheral edge 30A of the resistance member 30 in contact with the opening edge 25A of the through hole 25 can be deformed (elastically deformed) in the same direction.
At this time, when the upward lift of the support body 22 becomes a large value exceeding the elastic limit point of the resistance member 30 (for example, when a large earthquake occurs), the resistance member 30 undergoes plastic deformation and fracture, As a result, it is possible to prevent the upper lift F of the support 22 from being transmitted to the pier 21 via the anchor bolt 24.

A specific experimental example will be described with reference to FIG.
FIG. 3 shows the relationship between the amount of displacement (shown on the x-axis) and the load (shown on the y-axis) applied to the anchor bolt 24 when an upward lift is applied to the support body 22. Indicates the measurement result of the bridge girder support structure 100 of the present invention as “m1” and the measurement result of the conventional bridge girder support structure 1 (see FIG. 4) as “m2”.
As can be seen with reference to these measurement results (m1, m2), in the conventional bridge girder support structure 1, as indicated by the reference numeral m2, the greater the lifting force applied to the support body 22, the more it is applied to the anchor bolt 24. The load also increases, and eventually the concrete breakage of the pier 21 occurs via the anchor bolt 24 (destruction occurs at the point indicated by the symbol x).
However, in the bridge girder support structure 100 of the present invention, as shown by reference numeral m1, when an upward lift equal to or more than the value indicated by “x1” is applied to the support body 22, as shown in FIG. Since the washer serving as the resistance member 30 undergoes plastic deformation, no further upward lift acts on the anchor bolt 24, thereby preventing concrete breakage of the pier 21.
Further, when the washer serving as the resistance member 30 is plastically deformed, the support 22 inserted through the upper end portion 24B of the anchor bolt 24 may come off upward.
Therefore, in order to prevent such a problem, the length of the upper end portion 24B of the anchor bolt 24 protruding from the pier 21 and through which the resistance member 30 is inserted, as shown in FIG. It is desirable to set the dimension (indicated by the symbol A) so that the body 22 does not come out upward, for example, about 10 cm.

As described above in detail, according to the bridge girder support structure 100 shown in the present embodiment, the resistance member 30 located on the through hole 25 of the support 22 has a larger diameter than the through hole 25 of the support 22. At the same time, a nut 31 for holding the resistance member 30 is formed to have a smaller diameter than the through hole 25 of the support body 22, whereby the peripheral edge 30 A of the resistance member 30 in contact with the opening edge 25 A of the support body 22 31 does not overlap in the horizontal direction (arrow (b) direction), and can be easily deformed when pressed by the opening edge 25A of the support body 22.
Thereby, in the bridge girder support structure 100 shown in the present embodiment, when a strong upward lift F is generated in the support body 22 integrated with the bridge girder at the time of an earthquake, the opening edge 25A of the support body 22 is formed. Can be deformed in the same direction. At this time, when the upward lift F of the support body 22 becomes a large value exceeding the elastic limit point of the resistance member 30 (for example, when a large earthquake occurs), the resistance member 30 is broken to undergo plastic deformation. As a result, it is possible to prevent the upper lift F of the support body 22 from being transmitted to the pier 21 via the anchor bolt 24, and to prevent the pier 21 from being broken.
That is, in the bridge girder support structure 100 shown in the present embodiment, of the forces acting on the anchor bolts 24 from the support body 22 during an earthquake, the force along the axial direction (the direction of the arrow (a)) of the anchor bolts 24 is reduced. By releasing the member 30 by deformation, it is possible to prevent the bridge pier 21 from being seriously damaged through the anchor bolt 24.

  Further, according to the bridge girder support structure 100 shown in the present embodiment, the resistance member 30 disposed between the opening edge 25A of the support body 22 and the nut 31 is formed in a ring shape so as to surround the anchor bolt 24 from the periphery. Since it is formed, the fastening force of the nut 31 can be evenly transmitted to the support body 22.

  Further, according to the bridge girder support structure 100 shown in the present embodiment, a bridge girder support structure can be constructed at low cost by using a washer that is a general-purpose product as the resistance member 30.

Further, according to the bridge girder support structure 100 shown in the present embodiment, the upper end portion 24B of the anchor bolt 24 protruding from the pier 21 is set to a size (A) such that the bearing body 22 does not come out upward when an earthquake occurs. .
Thus, in the bridge girder support structure 100, even if the resistance member 30 in the through hole 25 of the support body 22 relatively moves along the axial direction of the anchor bolt 24 (the direction of the arrow (a)), The bridge 22 does not fall off from the pier 21, and the damage caused by the earthquake can be minimized also in this point.
In the above embodiment, the resistance member 30 is formed by a ring-shaped member (in this example, a washer) having a diameter larger than the through-hole 25 of the support body 22, but the shape is not limited to a circle, but may be a square or a square. It may be a polygon.

  As described above, the embodiment of the present invention has been described in detail with reference to the drawings. However, the specific configuration is not limited to this embodiment, and includes a design change or the like without departing from the gist of the present invention.

  The present invention relates to a bridge girder support structure applied to bridges such as railway bridges and road bridges.

Reference Signs List 20 bridge 21 bridge pier 22 support body 24 anchor bolt 24A base end 24B upper end 25 through hole 25A opening edge 25a through hole diameter 30 resistance member 30A peripheral edge 30a resistance member diameter 31 nut 31a nut diameter 100 bridge girder support structure

Claims (2)

In a bridge in which a bridge girder is supported on a pier via a bearing,
An anchor bolt having an upper end provided so that a base end is embedded in the pier and protrudes upward from the pier,
A hole provided in the bearing body installed on the pier and through which an upper end of the anchor bolt is inserted;
A nut that is screwed to an upper end of the anchor bolt that penetrates the hole of the support body;
A resistance member disposed between the opening edge of the hole of the support and the nut and transmitting a fastening force of the nut to the support;
The resistance member deforms more than the anchor bolt with the vertical displacement of the support body ,
Along with the washer formed in a ring shape so as to surround the anchor bolt from the periphery ,
Formed in a shape larger than the hole of the support body,
The bridge girder support, wherein the nut is formed to have a smaller diameter than the hole of the support body, and is arranged at a position not overlapping in a horizontal direction with a peripheral edge of the resistance member which is in contact with an opening edge of the support body. Construction.   2. The bridge girder support structure according to claim 1, wherein an upper end portion of the anchor bolt protruding from the pier is set to a size such that the support body does not come out upward when an earthquake occurs.

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